Continuum Limits for Adaptive Network Dynamics

TL;DR

This paper develops a rigorous mathematical framework for continuum limits of large-scale adaptive network models, specifically for adaptive Kuramoto systems, enabling better analysis of co-evolving graph dynamics.

Contribution

It introduces and proves continuum limits for adaptive networks, expanding the mathematical understanding of large-scale co-evolving graph systems.

Findings

Established continuum limits for adaptive Kuramoto networks.

Provided a measure-theoretical framework for graph limits.

Applied the theory to neuroscience-inspired models.

Abstract

Adaptive (or co-evolutionary) network dynamics, i.e., when changes of the network/graph topology are coupled with changes in the node/vertex dynamics, can give rise to rich and complex dynamical behavior. Even though adaptivity can improve the modelling of collective phenomena, it often complicates the analysis of the corresponding mathematical models significantly. For non-adaptive systems, a possible way to tackle this problem is by passing to so-called continuum or mean-field limits, which describe the system in the limit of infinitely many nodes. Although fully adaptive network dynamic models have been used a lot in recent years in applications, we are still lacking a detailed mathematical theory for large-scale adaptive network limits. For example, continuum limits for static or temporal networks are already established in the literature for certain models, yet the continuum limit of fully adaptive networks has been open so far. In this paper we introduce and rigorously justify continuum limits for sequences of adaptive Kuramoto-type network models. The resulting integro-differential equations allow us to incorporate a large class of co-evolving graphs with high density. Furthermore, we use a very general measure-theoretical framework in our proof for representing the (infinite) graph limits, thereby also providing a structural basis to tackle even larger classes of graph limits. As an application of our theory, we consider the continuum limit of an adaptive Kuramoto model directly motivated from neuroscience and studied by Berner et al.~in recent years using numerical techniques and formal stability analysis.